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Shielding Gas. Gases for Welding Non-Ferrous Materials

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Shielding Gas. Gases for Welding Non-Ferrous Materials → Product Brochure Shielding gas. Gases for welding non-ferrous materials. 03 There is a wide range of aluminium, copper and titanium alloys used in a variety of industries such as in the aerospace, automotive, power generation and petro- chemical sector. These non-ferrous alloys can exhibit a wide range of mechanical, electrical and corrosion resistant properties, depending on the alloy system. However, they all have one property in common – they oxidise very easily during welding and are sensitive to moisture and impurity pick up by the weld. They are therefore not as easy to weld as the steel alloys and good welding technique/procedures, together with good housekeeping and cleanliness in and around the welding area, are essential in order to weld these materials successfully. VARIGON® is a registered trademark of The Linde Group. 04 Improved performance for MIG and TIG welding Improved performance for MIG and TIG welding. Both MIG and TIG welding are widely used for welding non-ferrous The choice of shielding gas for welding these materials is simple – alloys. The choice of process is similar to that for other alloys – only the inert gases are suitable. Consequently, the most common MIG for high productivity and TIG for high precision welding. gas mixtures for both MIG and TIG welding of aluminium, copper and titanium alloys are pure argon, pure helium and mixtures of the two. Titanium is also very sensitive to oxygen and nitrogen and may even require special low impurity products, especially for high quality applications. Small additions, usually less than 0.05 %, of oxidising gases have been shown to be beneficial additions to argon or argon and helium mixtures for welding aluminium. However, these are specialised applications and require welding engineering assessments to be carried out to ensure their suitability. Improved performance for MIG and TIG welding 05 VARIGON He30 06 The right gases for aluminium, copper and titanium alloys The right gases for aluminium, copper and titanium alloys. Gases for non-ferrous materials Thickness Thickness Welding Spatter Porosity range for range for speed control control Fusion Penetration Ease of use MIG (mm) TIG (mm) Argon 4.6 1 to 4 0 to 3 VARIGON He30 1 to 6 1 to 6 VARIGON He50 3 to 10 3 to 9 VARIGON He70 6 to 12+ 6 to 12+ The greater the number of dots, the better the gas performs. Argon 4.6 VARIGON He30 Argon is only suited for welding thin sections as it does not produce The addition of 30 % helium to argon improves the fluidity of the weld a very fluid weld pool. When used for MIG welding, it can give welds pool, whether the mixture is used for MIG and TIG welding. This mixture with high levels of reinforcement, as well as poor fusion and porosity is best suited for welding thin to medium section thicknesses either when welding thicker sections. If reinforcement levels are high, this manually or automatically. can increase stresses within the weld area, so it may be necessary to reduce these by machining. This adds another manufacturing process Fusion and penetration profiles are improved over pure argon, as are its increasing component costs. gap bridging capabilities, reducing the chances of burn through. The addition of helium also helps to lower the levels of porosity, reducing Poor fusion and penetration can also increase defect levels, especially defect rates. Which in turn helps to reduce the defect rates, lowering as the material thick ness increases. Porosity can also be a problem production costs and scrapping rates. when using argon caused by the fast freezing weld pool. All these problems increase costs through additional processes such as weld Preheating will still be required for welding most thicknesses of copper, repair or through the component having to be scrapped. but temperatures will be lower than for argon. This will save both the cost of the preheating medium and the time taken to reach the required When MIG or TIG welding copper, some level of preheating is normally temperature. required and as the thickness of the material increases, so does the preheat temperature required. Again this additional process and the length of time required to preheat adds cost into the component being manufactured. The right gases for aluminium, copper and titanium alloys 07 VARIGON He50 VARIGON He50 VARIGON He70 An addition of 50 % helium to this mixture produces a more fluid This 70 % helium and argon mixture is most commonly used for weld pool than with VARIGON He30 and so tends to be used on automatic MIG and TIG welding. It produces a very fluid weld pool thicker components. It can be used for both MIG and TIG welding, with excellent fusion and penetration and is ideal for welding very either manually or on automatic welding equipment. thick aluminium sections and copper. The fusion and penetration characteristics are significantly improved The fluid weld pool allows a significant increase in welding speed to over argon and much lower defect rates are achieved. Reinforcement be achieved over argon. The fusion characteristics and penetration levels are also much lower as the weld flows much easier giving flatter profile are improved and this reduces the defect level minimising the weld profiles. Welding speeds can also be improved while maintaining number of rejected components, increasing productivity and efficiency the weld quality. All the features improve productivity while reducing while reducing overall production costs. production costs. Even smaller weld preparations can often be used than with The high energy available means that little or no preheating is VARIGON He50, giving a further economic advantage when using required when welding thicker aluminium sections or thinner copper this shielding gas. sections. In some cases the weld preparation can be reduced in size. This enables a con siderable cost saving as the cost to manufacture the weld preparation, the cost in wire and time to re-weld the joint are all reduced or eliminated. Getting ahead through innovation. With its innovative concepts, Linde is playing a pioneering role in the global market. As a technology leader, it is our task to constantly raise the bar. Traditionally driven by entrepreneurship, we are working steadily on new high-quality products and innovative processes. Linde offers more. We create added value, clearly discernible competitive advantages, and greater profitability. Each concept is tailored specifically to meet our customers’ requirements – offering standardised as well as customised solutions. This applies to all industries and all companies regardless of their size. If you want to keep pace with tomorrow’s competition, you need a partner by your side for whom top quality, process optimisation, and enhanced productivity are part of daily business. However, we define partnership not merely as being there for you but being with you. After all, joint activities form the core of commercial success. Linde – ideas become solutions. Linde AG Gases Division, Seitnerstrasse 70, 82049 Pullach, Germany Phone +49.89.7446-0, Fax +49.89.7446-1216, www.linde-gas.com .
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